ECONOMIC IMPACT ANALYSIS FOR THE POLYMERS AND RESINS GROUP I NESHAP REVISED DRAFT REPORT Prepared for: Office of Air Quality Planning and Standards U.S. Environmental Protection Agency Research Triangle Park, NC Prepared by: E.H. Pechan & Associates, Inc. 3500 Westgate Drive, Suite 103 Durham, NC E.H. Pechan & Associates, Inc. 5537-C Hempstead Way Springfield, VA January 11, 1995 EPA Contract No. 68-D1-0144, 68-D4-0107 Work Assignment No. 2-14, 0-1 Pechan Report No. 95.01.001/1150.001
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ECONOMIC IMPACT ANALYSIS
FOR THE POLYMERS AND RESINS GROUP I
NESHAP
REVISED DRAFT REPORT
Prepared for:
Office of Air Quality Planning and StandardsU.S. Environmental Protection Agency
Research Triangle Park, NC
Prepared by:
E.H. Pechan & Associates, Inc.3500 Westgate Drive, Suite 103
Durham, NC
E.H. Pechan & Associates, Inc.5537-C Hempstead Way
ES-1. MODEL DEVELOPMENT FOR ECONOMIC IMPACT ANALYSIS. . . . . . . . . . . . . . . . . ES-72-1. DISTRIBUTION OF AFFECTED FACILITIES BY STATE AND EPA REGION.. . . . . . . . . 172-2. PRODUCTION OF STYRENE-BUTADIENE RUBBER, POLYBUTADIENE
ASM Annual Survey of ManufacturesBCA Benefit Cost AnalysisBR polybutadiene rubberCAA Clean Air ActDOC U.S. Department of CommerceEIA economic impact analysisEPA U.S. Environmental Protection AgencyEPI epichlorohydrin elastomersEPD ethylene-propylene copolymersEPDM ethylene-propylene rubberEPI epichlorohydrin elastomersGDP gross domestic productHAPs hazardous air pollutantsHNBR hydrogenated butyl rubberHON Hazardous Organic NESHAPIISRP International Institute of Synthetic Rubber ProducersITC International Trade CommissionMACT maximum achievable control technologyMRR monitoring, recordkeeping, and reportingNBL nitrile-butadiene latexNBR nitrile-butadiene rubberNESHAP national emission standard for hazardous air pollutantsRFA Regulatory Flexibility ActSBA U.S. Small Business AdministrationSBL styrene-butadiene latexSBR styrene-butadiene rubberSIC Standard Industrial ClassificationTPEs thermoplastic elastomers2SLS two-stage least squares
viii
EXECUTIVE SUMMARY
ES.1 ECONOMIC IMPACT ANALYSIS OBJECTIVES
The purpose of this economic impact analysis (EIA) is to evaluate the effect of the control costs
associated with the final Polymers and Resins Group I National Emission Standard for Hazardous Air
Pollutants (NESHAP) on the behavior of the regulated synthetic rubber (elastomer) facilities. The EIA
was conducted based on the cost estimates for one regulatory option chosen by the U.S. Environmental
Protection Agency (EPA) for the regulation of 35 affected facilities. This analysis compares the
quantitative economic impacts of regulation to baseline industry conditions which would occur in the
absence of regulation. The economic impacts of regulation are estimated for each of the affected
industries, using costs which were supplied on a facility level.
Section 112 of the Clean Air Act (CAA) contains a list of hazardous air pollutants (HAPs) for which
EPA has published a list of source categories that must be regulated. To meet this requirement, EPA is
evaluating NESHAP alternatives for the regulation of industries classified within the Polymers and
Resins Group I source category, based on different control options for the emission points within
elastomer facilities which emit HAPs. This economic analysis analyzes the potential impacts of
regulation on the following eleven affected synthetic rubber industries:
! butyl rubber;
! ethylene - propylene rubber (EPDM);
! epichlorohydrin rubber (EPI);
! halobutyl rubber;
! Hypalon:
! nitrile-butadiene latex (NBL);
! nitrile-butadiene rubber (NBR);
! Neoprene;
ES-1
! styrene butadiene latex (SBL);
! styrene butadiene rubber (SBR); and
! polybutadiene rubber (BR).
Throughout this report, the term, Group I industries, refers collectively to all of the industries listed
above. This report presents the results of the economic analysis prepared to satisfy the requirements of
Section 317 of the CAA which mandates that EPA evaluate regulatory alternatives through an EIA.
The objective of this EIA is to quantify the impacts of NESHAP control costs on the output, price,
employment, and trade levels in the markets for each of the Group I elastomers. The probability of
synthetic rubber facility closure is also estimated, in addition to potential effects on the financial
conditions of affected firms. To comply with the requirements of the Regulatory Flexibility Act (RFA),
attention is focused on the potential effects of control costs on the smaller affected firms relative to larger
affected firms.
ES.2 INDUSTRY CHARACTERIZATION
The firms affected by the Polymers and Resins Group I NESHAP operate facilities that produce
butyl rubber, EPDM, EPI, halobutyl rubber, Hypalon, NBL, NBR, Neoprene, SBL, SBR, or BR. The
production of these synthetic rubbers is categorized under Standard Industrial Classification (SIC) code
2822. Synthetic rubbers are formed through the vulcanization process, which converts a rubber
hydrocarbon from a soft thermoplastic into a strong thermoset with specific elasticity and yield
properties.
The principle use of the synthetic rubbers in Group I is as an input to tire production, which
accounts for 60 percent of the use of domestically produced synthetic rubbers. Butyl rubber, SBR, and
BR are synthetic rubbers whose primary use is for tire manufacture. These three elastomers are
characterized by resistance to cracking and abrasion, and stability over time. The remaining eight
elastomers are used as inputs to the production of many diverse types of products, including components
for machinery and equipment, wire covering, construction products, and consumer items. Group I
elastomers are frequently in competition with each other for end uses. EPDM is a low cost elastomer
with a wide range of applications, among which automotive and appliance uses have been particularly
significant. NBR is the preferred elastomer for gasoline hoses, gaskets, and printing rolls. Neoprene
differs from BR, SBR, butyl rubber and EPDM because it is costlier and does not possess characteristics
ES-2
which make it favorable for use in automobile tires. Its primary use is in hose applications. Hypalon is
frequently used as a substitute for most of the other standard elastomers, such as uses which demand
resistance to heat and oil. EPI is used primarily in the production of automotive parts including hoses
and gaskets.
The proposed regulation will affect 35 synthetic rubber facilities, which are owned and operated by
18 firms. Synthetic rubber facilities are mainly owned by oil and chemical companies, rubber product
manufacturers, or independents. Butyl rubber, Hypalon, and EPI are supplied by only one firm. The
markets for the remaining elastomers are fairly unconcentrated.
ES.3 CONTROL COSTS AND COST-EFFECTIVENESS
The Polymers and Resins Group I NESHAP would require sources to achieve emission limits
reflecting the application of the maximum achievable control technology (MACT) to four affected
emission points. This EIA analyzes one regulatory alternative which was chosen by EPA. The chosen
regulation is the same as the Hazardous Organic NESHAP (HON) rule for all of the emission points
within Group I elastomer facilities. For existing sources, the MACT floor was based on the CAA
stipulation that the minimum standard represent the average emission limitation achieved by the best
performing 12 percent of existing sources. No new source costs were included in this analysis given that
little new source construction is likely in this industry within the next five years.
Control costs were developed for the following major emission points within elastomer facilities:
equipment leaks, front- and back-end process vents, wastewater collection and treatment systems, and
storage tanks. Cost estimates were annualized for the fifth year after promulgation of the Polymers and
Resins Group I NESHAP and are expressed in 1989 dollars throughout this report. Economic impacts
were estimated based on the facility-level costs for the proposed alternative, which represent the cost of
the MACT floor option for all four emission points. Table ES-1 presents the total investment capital
costs and national annualized cost estimates for controlling existing sources. These costs were prepared
by the engineering contractor for use in the EIA. Costs are provided by industry for the MACT floor
level of control. The total national annualized cost for implementation of the regulatory alternative is
approximately $21 million [including monitoring, reporting, and recordkeeping (MRR) costs], and the
total capital cost estimate is approximately $26 million for the 11 affected industries five years
subsequent to promulgation of the regulation.
ES-3
Table ES-1 also shows the HAP emission reductions associated with control at the four emission
points and the calculated cost-effectiveness of each control method. The HAP emission reductions were
calculated based on the application of sufficient controls to each emission point to bring the point into
compliance with the regulatory alternative. The cost-effectiveness of the predicted HAP emission
reduction ranges from $1,710 to $9,205 per megagram, or an average of $3,311 per megagram of HAP
reduced for the proposed NESHAP.
ES.4 ECONOMIC METHODOLOGY OVERVIEW
In this study, data inputs are used to construct a separate, pre-control baseline equilibrium market
model of ten of the eleven affected industries. Hypalon was not modeled due to the fact that emission
control costs including MRR are estimated to be zero for this industry. The baseline models of the
markets for these ten synthetic rubbers provide the basic framework necessary to analyze the impact of
proposed control costs on these industries. The Industry Profile for the Polymers and Resins I NESHAP
contained industry data that are used as inputs to the baseline models and to the estimation of price
elasticities of demand and supply. The industry profile includes a characterization of the market
structure of each affected industry, provides necessary supply and demand data, and identifies market
trends. Engineering control cost studies provide the final major data input required to quantify the
potential impact of control measures on the affected markets. These economic and engineering cost data
inputs are evaluated within the context of the market model to estimate the impacts of regulatory control
measures on
ES-4
TABLE ES-1. SUMMARY OF GROUP I NESHAP COSTS IN THE FIFTH YEAR BY ELASTOMER INDUSTRY
Group I Industry
Fifth Year
Capital Costs
(1989 Dollars)
Annual Fifth Year
Costs
(1989 Dollars)
Annual HAP
Emission Reduction
(Mg/yr)
Cost-Effectiveness
($/Mg)
Butyl Rubber $691,158 $1,458,870 596 $2,448
EPDM $5,956,585 $4,589,591 2,087 $2,199
EPI $491,203 $296,582 124 $2,392
Halobutyl Rubber $328,055 $572,946 335 $1,710
Hypalon $0 $0 0 $0
NBL $464,737 $291,467 140 $2,082
NBR $397,265 $675,971 365 $1,852
Neoprene $560,205 $959,728 354 $2,711
SBL $1,480,479 $1,212,387 583 $2,080
SBR $3,941,869 $2,190,864 238 $9,205
BR $11,780,263 $8,745,806 1,519 $5,758
TOTAL FOR REGULATORY ALTERNATIVE $26,091,819 $20,994,211 6,341 $3,311
each of the Group I industries and on society as a whole. The potential impacts include the following:
C Changes in market price and output;
C Financial impacts on affected firms;
C Predicted closure of affected synthetic rubber facilities;
C Welfare analysis;
C Small business impacts;
C Labor market impacts;
C Energy use impacts;
C Foreign trade impacts; and
C Regional impacts.
The progression of steps in the EIA process is summarized in Figure ES-1.
ES.5 PRIMARY REGULATORY IMPACTS
Primary regulatory impacts include estimated increases in the market equilibrium price of each
Group I elastomer, decreases in the market equilibrium domestic output or production of each elastomer,
changes in the value of domestic shipments, and facility closures. The analysis was conducted separately
for each of the ten affected industries. No impacts have been reported for the Hypalon industry since no
emission control costs are anticipated for this industry. The primary regulatory impacts are summarized
in Table ES-2.
As shown in Table ES-2, the estimated price increases for each of the Group I industries range from
a low of $0.002 per kilogram for halobutyl to a high of $0.022 per kilogram for EPI, based upon 1989
price levels. These predicted price increases represent percentage increases ranging from a low of 0.18
percent for NBL to a high of 2.5 percent for butyl rubber. Domestic production will decrease for each of
the Group I synthetic rubbers in amounts ranging from 0.08 million kilograms for EPI to 24.53 million
kilograms for BR. This estimated percentage decrease in annual production for each of the elastomers
varies from a low of 0.69 percent for NBL to a high of 4.95 percent for butyl rubber.
ES-6
FIG ES-1. MODEL DEVELOPMENT FOR ECONOMIC IMPACT ANALYSIS
ES-7
TABLE ES-2. SUMMARY OF PRIMARY ECONOMIC IMPACTS OFPOLYMERS AND RESINS GROUP I NESHAP
NOTES: Brackets indicate decreases or negative values.1
Indicates estimated reduction in number of jobs.2
Reduction in energy use in millions of 1989 dollars.3
Reduction in net exports (exports less imports) are expressed in millions of kilograms.4
Hypalon is omitted from the analysis.5
ES-10
Regional effects are expected to be minimal since the affected facilities are dispersed throughout the
United States. Given that the market impacts are predicted to be minimal in most cases, it follows that no
region of the country will be significantly adversely affected by the regulation.
ES.7 ECONOMIC COST
Air quality regulations affect society's economic well-being by causing a reallocation of productive
resources in the economy. Resources are allocated away from the production of goods and services
(Group I elastomers) to the production of cleaner air. Economic costs represent the total cost to society
associated with this reallocation of resources.
The economic costs of regulation incorporate costs borne by all of society for pollution abatement.
The social, or economic, costs reflect the opportunity cost of resources used for emission control.
Consumers, producers, and all of society bear the costs of pollution controls in the form of higher prices,
lower quantities produced, and possible tax revenues that may be gained or lost. Annual economic costs
of $15 million ($1989) are anticipated for the chosen alternative and are shown by industry in Table ES-
4. Economic costs are a more accurate estimate of the cost of the regulation to society than the cost of
emission controls to the directly affected industry.
ES.8 POTENTIAL SMALL BUSINESS IMPACTS
The RFA requires that a determination be made as to whether or not the subject regulation would
have a significant economic impact on a substantial number of small entities. The majority of affected
Group I producers are large chemical companies, and, consequently, significant small business impacts
are not expected to result from implementation of the Polymers and Resins Group I NESHAP. Based on
available employment data for each of the 18 affected firms, five firms classify as small businesses. Of
these, three are unaffiliated with a larger business firm. Costs expressed as a percentage of sales for
these three firms do not indicate that the NESHAP will result in adverse economic impacts.
ES-11
TABLE ES-4. ANNUAL ECONOMIC COST ESTIMATES FOR THE POLYMERS AND RESINSGROUP I REGULATION1
(millions of 1989 dollars)2
Group IIndustry
Change inConsumer
Surplus
Change inProducerSurplus
Change inResidualSurplus
Total LossIn Surplus
Butyl Rubber ($0.48) ($0.59) ($0.29) ($1.36)
EPDM ($3.61) $0.27 $0.46 ($2.88)
EPI ($0.11) ($0.11) ($0.03) ($0.25)
Halobutyl Rubber ($0.19) ($0.24) ($0.11) ($0.54)
NBL ($0.12) ($0.12) ($0.04) ($0.28)
NBR ($0.41) ($0.17) ($0.07) ($0.65)
Neoprene ($0.64) ($0.01) $0.02 ($0.63)
SBL ($2.97) $1.30 $0.78 ($0.89)
SBR ($2.52) $0.57 $0.50 ($1.45)
BR ($9.12) $1.56 $1.38 ($6.18)
Total ($20.17) $2.46 $2.60 ($15.11)
NOTES: Hypalon is omitted from the analysis.1
Brackets indicate economic costs.2
ES-12
1.0 INTRODUCTION AND SUMMARY OF CHOSEN REGULATORY
ALTERNATIVE
1.1 INTRODUCTION
Section 112 of the CAA contains a list of HAPs for which EPA has published a list of source
categories that must be regulated. EPA is evaluating alternative NESHAPs for controlling HAP
emissions occurring as a result of the production of specific types of synthetic rubbers (elastomers).
These affected industries are categorized within the Polymers and Resins Group I source category. This
report evaluates the economic impact of the standard on the industries manufacturing the following
synthetic rubbers:
! butyl rubber;
! ethylene - propylene rubber (EPDM);
! epichlorohydrin rubber (EPI);
! halobutyl rubber;
! Hypalon:
! nitrile-butadiene latex (NBL);
! nitrile-butadiene rubber (NBR);
! Neoprene;
! styrene butadiene latex (SBL);
! styrene butadiene rubber (SBR); and
! polybutadiene rubber (BR).
This analysis was conducted to satisfy the requirements of Section 317 of the CAA which mandates that
EPA evaluate regulatory alternatives through an EIA.
1
This chapter presents a discussion of the NESHAP alternative under analysis in this report. Chapter
2 of this report is a compilation of economic and financial data on the eleven affected industries included
in this analysis. Chapter 2 also presents an identification of affected synthetic rubber facilities, a
characterization of market structure, separate discussions of the factors which affect supply and demand,
a discussion of foreign trade, a financial profile, and the quantitative data inputs for the EIA model.
Chapter 3 outlines the economic methodology used in this analysis, the structure of the market model,
and the process used to estimate industry supply and demand elasticities.
Chapter 4 presents the control costs used in the model, the estimated emission reductions expected
as a result of regulation, and the cost-effectiveness of the regulatory option. Also included is a
quantitative estimate of economic costs and a qualitative discussion of conceptual issues associated with
the estimation of economic costs of emission controls. Chapter 5 presents the estimates of the primary
impacts determined by the model, which include estimates of post-NESHAP price, output, and value of
domestic shipments in each of the affected industries. A capital availability analysis is also included in
this chapter as well as a discussion of the limitations of the model. Chapter 6 presents the secondary
economic impacts, which are the estimated quantitative impacts on the industry's labor inputs, energy
use, balance of trade, and regional markets. Lastly, Chapter 7 specifically addresses the potential impacts
of regulation on affected firms which classify as small businesses based on the standards set by the U.S.
Small Business Administration (SBA). Appendix A presents the results of sensitivity analyses conducted
to quantify the extent to which the price elasticities of demand and supply affect the results of the
models.
1.2 SUMMARY OF CHOSEN REGULATORY ALTERNATIVE
The CAA stipulates that HAP emission standards for existing sources must at least match the
percentage reduction of HAPs achieved by either: (1) the best performing 12 percent of existing sources,
or (2) the best 5 sources in a category or subcategory consisting of fewer than 30 sources. For new
sources, the CAA stipulates that, at a minimum, the emission standard must be set at the highest level of
control achieved by any similar source. This minimum level of control for both existing and new sources
is referred to as the MACT floor.
A source within a Group I synthetic rubber facility is defined as the collection of emission points in
HAP-emitting production processes within the source category. The source comprises several emission
points. An emission point is a piece of equipment or component of production which produces HAPs.
2
The NESHAP considered in this EIA requires controls on the following emission points in synthetic
rubber-producing facilities: storage tanks, equipment leaks, front- and back-end process vents, and
wastewater collection and treatment systems. EPA chose one regulatory alternative for each of the
regulated industries. The results of a detailed economic impact analysis for each of them are presented in
this report.
EPA provided cost estimates for controls deemed appropriate as options for each affected elastomer-
producing process at existing facilities. EPA determined that no new source costs will be included in this
analysis, based on an industry source which reported that no industry growth or capacity expansion is
expected to occur in the United States within the next 10 years . Costs represent the impact of bringing1
each facility from existing control levels to the control level defined by the regulatory alternative for each
emission point. The proposed Group I regulatory alternative chosen for this analysis closely resembles
the HON rule. The provisions of the single regulatory alternative developed for storage tanks,2
wastewater streams, and equipment leaks are identical to those required by Part 63 of the HON rule. The
process vent provisions also resemble the HON with the exception of provisions for some vents. For
batch processes and back-end process vents, the regulatory alternative is based on EPA's draft CTG for
Batch Processes. In either situation, the applicability of control requirements is based on vent stream3
characteristics. For the regulatory alternative examined in this EIA, costs were provided on a facility
level.
3
REFERENCES
1. Norwood, Phil. EC/R Incorporated. Telephone communication with Britt Theisman, InternationalInstitute of Synthetic Rubber Producers (IISRP). Durham, NC. July 14, 1994.
2. U.S. Environmental Protection Agency. "Hazardous Air Pollutant Emissions from Process Units inthe Synthetic Organic Manufacturing Industry - Background Information for Proposed Standards. Volume 1B: Control Technologies." Draft EIS. EPA-453/D-92-0166. Research Triangle Park,NC. November 1992.
3. U.S. Environmental Protection Agency. "Control of Volatile Organic Compound Emissions fromBatch Processes." Draft Document. EPA-453/R-93-017. Research Triangle Park, NC. November1993.
4
2.0 INDUSTRY PROFILE
2.1 INTRODUCTION
This chapter focuses on the markets for Group I elastomers. The economic and financial
information in this chapter characterizes the conditions in these industries which are likely to determine
the nature of economic impacts associated with the implementation of the NESHAP. The quantitative
data contained in this chapter represent the inputs to the economic model (presented in Chapter 3) which
were used to conduct the EIA. The general outlook for the affected Group I industries is also discussed
in this chapter.
Section 2.2 describes the elastomer production process, and identifies the unique market
characteristics of each elastomer. Section 2.2 also identifies the affected elastomer facilities by industry
location and production capacity. Section 2.3 characterizes the structure of the affected industries in
terms of market concentration and firm integration. Also included in Section 2.3 is a financial profile of
affected firms. Section 2.4 characterizes the supply side of the market based on production trends,
supply determinants, and export levels. Section 2.5 presents demand-side characteristics, including end-
use markets, consumption trends, and import levels. Lastly, Section 2.6 presents a discussion of the
outlook for Group I synthetic rubbers based on both a literature search for published forecasts, and on
anticipated future conditions in the market as determined by the industry data contained in this chapter.
2.2 IDENTIFICATION OF AFFECTED FIRMS AND FACILITIES
This section reviews the products and processes of the affected synthetic rubber industries. The
affected firms are identified by capacity, employment, and location of facilities. An EIA requires that
affected facilities in the industry be classified by some production factor or other descriptive
characteristic. Throughout this section, capacity will be used as a measure of size, since it is the one
5
characteristic that is consistently available for each synthetic rubber producer. (In this report, the term
firm refers to the company or producer, while facility refers to the actual rubber production site or plant.)
2.2.1 General Process Description
Synthetic rubber production requires the synthesis of monomers (derived from petrochemicals),
followed by their polymerization. This process results in an aqueous suspension of rubber particles, or
the latex, which may then be processed into marketable, dry, raw rubber. Synthetic rubbers are usually
compounded with various additives and then molded, extruded, or calendared into the desired solid form.
A percentage of elastomer production is also supplied in the form of water dispersions, called latexes
(primarily used in foam rubber). HAP emission sources in synthetic rubber facilities include: equipment
leaks, process vents, wastewater, and storage tanks. It is important to note that elastomer production1
sites subject to this standard may be collocated with other production facilities that are, or will be,
subject to MACT standards other than the Group I NESHAP. For example, a refining facility, chlorine
plant, SOCMI facility, or non-elastomer polymer facility could be located on the same site as Group I
production units.
2.2.2 Product Description
The affected Group I elastomers are classified as synthetic rubbers which have specific elasticity
and yield properties. Synthetic rubbers are either used as stand-alone products, or are compounded with
natural rubber, other thermoplastic materials, or additives, depending on the desired end-use
characteristics. This section describes the properties of each elastomer individually and identifies its
primary end uses.
2.2.2.1 Butyl Rubber. In addition to butyl rubber, this category includes chlorobutyl rubber,
bromobutyl rubber, and halobutyl rubber. Butyl rubbers are copolymers of isobutylene isoprene, and are
among the most widely used synthetic elastomers worldwide. Characteristics of butyl rubber include low
permeability to gases and high resistance to tear and aging. Eighty percent of butyl rubber produced is
used as an input to the production of tires, tubes, and tire products. Butyl rubber is also used in the
production of inner tubes because of its low air permeability. The remaining 20 percent of butyl rubber
is used in the production of automotive and mechanical goods, adhesives and caulks, and also for various
other uses, including pharmaceutical stoppers.
6
2.2.2.2 Styrene-Butadiene Rubbers and Latexes. SBR is produced in the largest volume of all the
synthetic rubbers. Its chemical properties include favorable performance in extreme temperatures,
resistance to cracking and abrasion, and stability over time. The dominance of SBR among synthetic
rubber types is attributable to the following two market conditions: availability and processability. The
availability of styrene and butadiene in fossil hydrocarbons make these two inputs an abundant source of
synthetic rubber, and styrene and butadiene can be combined into rubber compounds which are easily
processed into tire molds. Types of SBR differ in the ratios of styrene to butadiene, their content of
additives, or the type of polymerization process used during the manufacturing process. The
substitutability of SBR with natural rubber is primarily determined by the fluctuating prices of each, and
by the properties required in the end product.
As with butyl rubber, the primary use of SBR is in the production of tires, although the percentage
of SBR used for tires is lower than that of butyl rubber. Additional end use categories for SBR include
mechanical goods, automotive parts, floor tiles, and shoe soles. Approximately 10 percent of SBR
produced is in latex form (SBL), which is used for carpet backing, nonwoven materials, and paper
coatings. Latexes typically have a higher percentage of styrene than SBR and are also used in the
construction industry.
2.2.2.3 Polybutadiene Rubber. BR is formed from butadiene which undergoes emulsion
polymerization. After SBR, polybutadiene rubber is the synthetic rubber produced in the second highest
volume. The use of polybutadiene in tires is due to its resistance to abrasion, high resiliency, favorable
temperature flexibility, and resistance to tread cracking. BR may also be blended with natural rubber to
improve abrasion resistance. Similar to butyl rubber and SBR, the primary use of BR is for tires and tire
products (68 percent). BR is also used as a styrene resin modifier, in the production of ABS for example,
as well as for an input to the manufacture belts and hoses.
2.2.2.4 Ethylene-Propylene Rubber. The ethylene-propylene category includes both ethylene-
propylene copolymers (EPD), and ethylene-propylene terpolymers (EPDM). EPDM is produced from
the polymerization of ethylene and propylene. EPDM is characterized by poor adhesion and slow curing,
which makes blending with other rubbers difficult. Advantages to using EPDM include low cost,
resistance to cracking, and low temperature flexibility. After SBR and BR, EPDM is third in terms of
production volume of all the synthetic rubbers. EPDM compounds have been developed for a great
variety of applications, among which automotive and appliance uses have been particularly significant.
End uses include roofing membranes, impact modifiers, oil additives, automobile parts, gaskets and seals,
7
and hoses and belts. The wide range of uses of this elastomer is attributable to its multifunctional nature.
2.2.2.5 Nitrile Butadiene Rubber. NBR is a copolymer of acrylonitrile and butadiene. Its most
significant characteristic is its resistance to oil. NBR is the preferred product for gasoline hoses, gaskets,
and printing rolls. Many of the properties of nitrile rubber are directly related to the proportion of
acrylonitrile in the rubber. NBR is used in many hose applications where oil, fuel, chemicals, and
solutions are transported. In powder form, NBR is used in cements, adhesives, and brake linings, and in
plastics modification. NBR is also used in belting and cable, in addition to its uses in O-rings and seals,
adhesives and sealants, sponges, and footwear.
2.2.2.6 Neoprene. Polychloroprene, also known as Neoprene, is produced from chloroprene
through an emulsion process. Neoprene differs from BR, SBR, butyl rubber, and EPDM because it is
costlier and does not possess characteristics which make it favorable for use in automobile tires. Its
flexibility, high resistance to oils, strength, and resistance to abrasion, however, make it suitable for other
diverse uses. Neoprene is similar to NBR in end uses, given that the primary use is for hoses and belts,
with the remainder allocated among mechanical, adhesive, and wire and cable end uses. Manufacturers
of shoes, aircraft, automobiles, furniture, building products, and industrial components rate Neoprene
adhesives as a versatile material for adhesive purposes. The oldest use of Neoprene is as a jacket for
electrical conductors in such products as appliances and telephone wires. In latex form, Neoprene is used
to manufacture household and industrial gloves.
2.2.2.7 Hypalon. Chlorosulfonated polyethylene, also known by the trade name Hypalon, is formed
solely from polyethylene through a chlorination and chlorosulfonation process. Although a breakdown
of Hypalon among end uses was not available, it is used as a substitute for most of the other standard
elastomers, including uses which demand resistance to heat and oil. Uses of Hypalon include coatings
for roofs and tarpaulins, hose construction, wire coverings, industrial rolls, and sporting goods.
2.2.2.8 Epichlorohydrin Elastomers. The production of EPI uses epichlorohydrin, ethylene oxide,
and allyl glycetal ether, which are combined in a polymerization process. Information on
epichlorohydrin elastomers was limited. Its primary use is as an automotive rubber, for applications
including gaskets and hoses.
2.2.3 Affected Elastomer Facilities, Employment, and Location
8
The NESHAP will affect 35 facilities, which are owned and operated by 18 firms. SBR production
as a whole (SBR and SBL) includes the highest number of producers of any of the other rubber types in
Group I. Table 2-1 shows the distribution of production capacity among the producers of SBR and SBL.
The top four firms share 70 percent of the total industry SBR capacity. Uniroyal Goodrich Tire
Company and The Goodyear Tire & Rubber Company own 32 percent and 37 percent of SBR capacity,
respectively. The remaining 5 SBR manufacturers operate between 3 percent and 11 percent of industry
capacity. The SBL market is less concentrated than that of SBR. Reichhold Chemical is the dominant
firm, with 29 percent of industry capacity; Dow Chemical owns the next highest percentage at only 23
percent of capacity.
The production capacity for BR manufacturers is listed by firm and facility location in Table 2-2.
The capacity for producing polybutadiene rubber is shared by four firms. The market concentration in
this industry subcategory is more concentrated than in the SBR industry. The Goodyear Tire & Rubber
Company owns the highest degree of production capacity, with 50 percent of the total. The second
largest producer is Bridgestone/ Firestone Inc., with 26 percent of industry capacity. The top two firms
in the polybutadiene rubber industry share 76 percent of capacity, indicating a high level of market
NOTES: Rubber types have been abbreviated as follows: SBR = styrene-butadiene rubber, SBL = styrene-butadiene latex, BR = polybutadiene rubber, EPI = epichlorohydrin elastomers,a
NBR = nitrile butadiene rubber, EPDM = ethylene-propylene rubber, NBL = nitrile butadiene latex.SBR, EPDM, and BR capacities are based on net rubber (oil content is included, but carbon black and other fillers are excluded).b
Capacity is also utilized to produce SBR.c
N/A = Not available.
2.3.1 Market Concentration
Market concentration in an industry is an indication of the control that firms have over their pricing
policies. Market concentration is typically expressed as the percentage of industry output controlled by
the largest firms; however, for Polymers and Resins Group I, the necessary production data on a firm
level by rubber type were not accessible. For this analysis, therefore, market concentration in each of the
Group I industries was assessed in terms of production capacity rather than by a specific measure of
elastomer output. Because butyl rubber, halobutyl rubber, Hypalon, and EPI are each produced by only
one firm, market concentration will not be considered for these four industries.
Uniroyal Goodrich and Goodyear Tire & Rubber dominate the market for SBR, with the remainder
of production capacity allocated among 5 producing firms. Market concentration among SBL producers
is more highly concentrated in the hands of fewer producers. Reichhold Chemical is the primary
producer of SBL, operating 29 percent of total national SBL capacity. The remaining SBL capacity is
owned and operated by 7 other firms. The majority of the national polybutadiene production capacity is
owned by the Goodyear Tire & Rubber Company with 50 percent of the total, with the second largest
producer being Bridgestone/Firestone Inc. with 26 percent of industry capacity. The remaining 24
percent of BR capacity is shared by 4 other firms.
The EPDM industry is the least concentrated industry in the Group I source category. Capacity is
shared by 5 producers, with no one firm dominating the market. The market for NBR is dominated two
firms which collectively operate 63 percent of total industry capacity. The Goodyear Tire & Rubber
owns 37 percent of national capacity, followed by Copolymer Rubber & Chemical Corporation which
operates 26 percent of total capacity. Zeon Chemicals is the other major producer with 21 percent of
total national capacity. The major player in the NBL market is Miles Chemical with 95 percent of
industry capacity. Lastly, of the two firms in the Neoprene industry, DuPont controls 81 percent of total
industry capacity.
2.3.2 Industry Integration and Diversification
Synthetic rubber facilities are mainly owned by oil and chemical companies, rubber product
manufacturers (tires, for example), or independents. The majority of affected Group I firms are large
firms that are vertically integrated to the extent that the same firm supplies input for several stages of the
production and marketing process. The majority of firms in this industry own segments that are
20
responsible for the production of the chemical inputs which are manufactured for captive use in rubber
production. Other firms produce the rubbers being profiled in this report for captive use as an input into
rubber products, such as automobile tires. For example, as was shown in Table 2-1, the largest SBR
producers are Uniroyal Goodrich Tire Company and The Goodyear Tire & Rubber Company. Each of
these firms is a significant player in the global tire market. The world tire industry is currently
characterized by overcapacity, lower profits than the historical average, and increased competition for
market share. As of December 1990, six producers controlled 80 percent of global tire production, a fact7
which reflects the high levels of consolidation in the past decade. In the past 2 years, further
consolidation has taken place. Goodyear, which is one of only two remaining domestic tire producers,
controls 28 percent of worldwide tire production. Goodyear also operates 52 percent of domestic
polybutadiene rubber capacity. (The majority of SBR and polybutadiene produced is used in tire
manufacturing.) This indicates that any potential effect of the Group I NESHAP on the polymers and
resins industry would also have a related and potentially significant effect on the global tire industry.
Firms that are vertically integrated could therefore be indirectly affected by the NESHAP in the factor
and product markets for various rubbers, particularly if demand for synthetic rubber decreases and
production in the tire market, for example, suffers as a result. Domestic tire producers, in particular,
could be adversely affected.
For the larger firms in this industry, horizontal integration exists to the extent that these firms
operate several plants which manufacture one or more Group I elastomers. Table 2-7 provided an
indication of the horizontal integration of the industry, as represented by the number of companies that
either operate several SBR facilities, for example, or supply more than one Group I elastomer. Of the 18
firms in the industry, 12 operate more than one plant. The major firms operate several plants, and the
largest, Dow, operates plants in five States. Of those firms producing more than one synthetic rubber
type, the Goodyear Tire & Rubber Company and Miles Inc. each manufacture four of the synthetic
rubbers in the Group I source category.
Diversification indicates the extent to which a firm has developed other revenue-producing
operations, in this case, in addition to synthetic rubber production. Many of the firms in the synthetic
rubber industry comprise larger corporations with a variety of product areas. Several are large players in
the oil industry, including Exxon and Unocal. E.I. Du Pont is a major firm in the chemical industry.
Other synthetic rubber producers are part of several other industries, such as Dow Chemical. Given that
many of the major firms in this industry are in divisions of large, diversified corporations, the financial
21
resources for capital investment in control equipment may be more accessible than for an industry
characterized by a large number of smaller firms.
2.3.3 Financial Profile
This subsection examines the financial performance of a sample of affected Group I firms. The
financial data presented here were obtained by request from Dun and Bradstreet's Supplier Evaluation
Reports. Although Dun and Bradstreet provided financial data for all 18 affected firms, the data8
reported for two firms were either too sparse for inclusion in the sample, or the categories reported were
inconsistent with the data provided for the other firms. To supplement the Dun and Bradstreet data,
information was obtained from a sample of the firms' annual reports.
Because the EIA is conducted on a firm level, it is useful to examine overall corporate profitability
as a preliminary indicator of the baseline conditions of affected firms in the industry. Corporate-level
data are also useful as an indication of the financial resources available to affected firms and the ability
of this capital to cover increased compliance costs after promulgation of the NESHAP.
Table 2-8 presents net income to assets ratios which were averaged from 1987 to 1991 for each firm.
Also presented are long-term debt to long-term debt plus equity ratios for the most current year for which
data were available. Net income to assets ratios are provided for 16 of the 18 affected firms, and range
from minus 6 percent for
22
TABLE 2-8. FINANCIAL STATISTICS FOR AFFECTED FIRMS8
Company
Net Income to Assets1987 to 1991 Average
(%)
Long Term Debt to LTDebt and Equity (%)
American Synthetic Rubber Company 3.7% 66.3%
BASF Corporation 18.4% N/A
Bridgestone/Firestone Inc. (6.4%) 68.1%
Copolymer (DSM) 2.1% N/A
Dow Chemical 8.7% 62.7%
E.I. DuPont de Nemours, Inc. 2.7% 60.7%
Exxon Corporation 5.9% 20.4%
Gencorp 3.5% 61.8%
General Tire Inc./Dynagen 3.4% N/A
Goodyear Tire & Rubber Company 4.2% 46.6%
Miles Inc. 2.2% 53.1%
Reichhold Chemicals, Inc. 1.3% N/A
Rhone-Poulenc, Inc. 11.5% 32.2%
Rohm & Haas 9.8% 35.1%
Uniroyal Chemical Company 10.4% N/A
W. R. Grace (Hampshire Chemical) 3.5% 46.7%
NOTE: N/A = not available.
23
Bridgestone/Firestone to 12 percent for Rhone-Poulenc. Long-term debt to equity ratios are provided for
11 of the 18 firms, and range from 20 percent for Exxon Corporation to 68 percent for
Bridgestone/Firestone. A financial impact analysis and capital availability analysis was completed based
on the results of the partial equilibrium analysis to determine the effect of NESHAP control costs on the
financial conditions of affected firms. The results of the capital availability analysis are presented in
Section 5.3 of this report.
2.4 MARKET SUPPLY CHARACTERISTICS
This section analyzes the supply side of the Group I industries. Historical production data are
presented, and the factors that affect production are identified. The role of foreign competition in this
industry is also assessed. The focus of this section is on overall industry supply and the existing
conditions in the marketplace.
2.4.1 Supply Trends
In recent years, overall domestic production of synthetic rubbers has remained below the peak levels
it reached in 1988. Synthetic rubber production fell in 1991 for the third consecutive year. These low
production levels have been attributed to a decrease in domestic automobile production, low levels of
economic activity, and higher import levels of automobile parts and other rubber products. Figure 2-2
shows the production levels from 1985 to 1991 for the three major synthetic rubber types classified in the
Group I source category. The overall growth rate for SBR during this time period was 18 percent.
Because SBR relies mainly on the tire industry for profits, producers have been harder hit by lower
automotive production than the other, more diversified Group I rubbers.
The growth rate for BR between 1985 and 1991 was 28 percent. Butyl rubber production data were
reported in a category which encompasses butyl rubber, Neoprene, Hypalon, polyisoprene, silicon, and
other synthetic elastomers. The production levels of this elastomer category have fluctuated during this
7-year period, and are currently at 1988 levels. Butyl rubber production, in particular, has declined due
to a decrease in demand from the inner tube market.
24
FIGURE 2-2. PRODUCTION OF STYRENE-BUTADIENE RUBBER, POLYBUTADIENE RUBBER
AND BUTYL RUBBER
25
Figure 2-3 shows similar production data for NBR and EPDM. The production of EPDM increased
fairly consistently during the 1980s, which was due to its increased use in wire and cable insulation,
roofing membranes, viscosity additives, automobile parts, and impact modifiers for thermoplastics. 10
Overall, NBR has shown very little growth during this time period.
2.4.2 Supply Determinants
Synthetic rubber production decisions are primarily a function of input prices, production costs,
elastomer prices, existing capacity levels, and international trade trends. Decisions made by producers
include determining which processors and markets to continue to serve and which facilities to continue
operating. Variations of synthetic rubbers are constantly being developed to satisfy the changing needs
of the rubber industry and its customers, and to provide greater raw material stability and upgraded
performance properties to meet new demands in end products. Profits depend on the productivity of the
elastomer production site. In the short run, a producer will manufacture a particular synthetic rubber
depending on the capacity of the facility and the cost of production. The marginal costs of production of
each elastomer will determine any future changes in production.
Generally speaking, synthetic rubber production is capital intensive, requiring relatively complex
production equipment and technology. The input cost that has the greatest impact on the production
decisions of producers in the rubber industry is that of crude oil, since synthetic rubbers are derived from
petroleum feedstock. Butadiene is a primary feedstock to the production of five of the major Group I
rubbers: SBR, SBL, NBL, BR, and NBR. Historically, the price of butadiene has been affected by the
price of crude oil. In recent years, synthetic rubber producers have been simultaneously faced with rising
feedstock costs and an inability to increase synthetic rubber prices accordingly because of the high levels
of price competition.11
Existing Federal, State, and local regulations can also have an impact on the quantity of elastomers
supplied by domestic facilities. Facilities that are already regulated may have previously altered their
production, and may therefore have already altered the industry supply schedule. The industry supply
curve used in the EIA for each Group I
26
FIGURE 2-3. PRODUCTION OF NITRILE BUTADIENE RUBBER AND ETHYLENE-PROPYLENE
RUBBER
27
industry incorporates any changes in production that have occurred as a result of other regulations to the
extent that the supply curve accounts for the level of existing controls at companies in each affected
industry.
Although it is beyond the scope of this profile to review all State and local regulations, some Federal
regulations are important to note here. The NESHAP for benzene will impact styrene producers, for
example, to the extent that benzene prices will have a direct effect on the production costs of styrene
producers. Styrene is a primary input to SBR and SBL production and any styrene price increases would
therefore increase production costs of both of these elastomers. In addition, the petroleum refining
NESHAP will affect firms in Group I industries which are also producers of petroleum products,
including, for example, Exxon Corporation. Because synthetic rubbers are produced from petrochemical
feedstocks, any impact on petroleum product prices will influence the affected Group I facilities.
Similarly, the NESHAPs for other groups in the Polymers and Resins categories are also likely to affect
many firms in Group I, which are diversified and produce several types of polymers and resins.
Competition takes place in the synthetic rubber market on two levels: among producers of the same
elastomer type, and among various synthetic rubbers with similar characteristics. In choosing the
appropriate rubber for a given application, end users consider performance and elastomer price. In
addition to competing with each other, Group I elastomers also compete with natural rubber in certain
end uses. Although natural rubber is unable to compete with specialty elastomers designed for a
particular use, its ease of processability and relatively low cost make it a substitute for several of the
synthetic rubbers in Group I. As stated earlier in this chapter, the largest volume of rubber is used for tire
manufacturing. The polymers used in tires include: natural rubber, SBR, polybutadiene, butyl, and some
EPDM. For use in a tire, the demands placed on the rubber type include resistance to cracks and
abrasion, flexibility, and stability over time. SBR, polybutadiene, and natural rubber each meet these
requirements after the vulcanization process.
The tradeoff between SBR and natural rubber for use in tire manufacturing has typically been one of
economics. SBR has more favorable abrasion resistance than natural rubber, but is poorer in heat
buildup. In certain instances, for example, in heavy-duty truck and bus tires, natural rubber is preferred
over SBR because of such properties as crack resistance. Because of a market switch to radial tires, the
percentage share of natural rubber relative to the percentage share of elastomers in the rubber market has
increased. Generally speaking, the advantage of synthetic rubber over natural rubber is the existence of
ample production capacity, widespread uses, and processing advantages.
28
Both Neoprene and natural rubber are options in end uses which demand flexibility and resilience.
Natural rubber competes with Neoprene for use in bridge bearings. For products with lower quality
including footwear, garden hoses, and mats, SBR and natural rubber are competitors, and both can be
mixed with high levels of reclaimed rubber to decrease production costs. In these applications where
SBR and natural rubber are more interchangeable, pricing plays a more significant role.
EPDM, butyl, Neoprene, EPI, and Hypalon are each resistant to ozone effects. SBR, BR, NBR, and
natural rubber are non-ozone resistant, but can be blended with other materials to achieve this property.
SBR and natural rubber are not suitable for uses which demand oil resistance, such as special grades of
hose, for example. Neoprene, NBR, and EPI are suitable in these uses. In cases where extreme heat
resistance is required, EPDM, butyl, Hypalon, Neoprene, and NBR are suitable. For uses which require
low temperature flexibility, EPDM, polybutadiene, natural rubber, and SBR are best.
The compounding process allows for any of the eleven synthetic rubbers in this report to be
modified to achieve a suitable property. Changes in demand specifications can significantly affect the
synthetic rubber market, which is characterized by similar products with diverse chemical properties.
NBR and Neoprene have both been negatively affected by weak automobile sales, while increased
demand for EPDM has been triggered by a necessity for high-performance, cost-effective rubber
components. EPDM has a more favorable cost performance ratio than NBR or Neoprene and, as a result,
market growth is predicted for EPDM in developing countries which are in a period of industrialization. 11
(EPDM prices hover around 45 cents per kilogram, while competing elastomers are typically higher.)
In addition to competing with each other, the commodity rubbers in Group I also compete with
specialty rubbers, which include thermoplastic elastomers (TPEs), silicones, and fluorocarbons. In 1991,
specialty rubbers supplied about 8 percent of domestic rubber demand, an increase of 5 percent from
1990. Benefits of TPEs include easier processability and recyclability. The costs of manufacturing12
TPEs are also lower than for vulcanizing the thermoset rubbers. In addition to the economic advantages
of TPEs, another favorable characteristic is that these elastomers can be designed to meet specific user
criteria. TPEs are not well-suited for use in tires, since they do not possess the wide temperature
performance range of most Group I rubbers, nor are the TPEs able to resist deformation at high
temperatures. As a result, the share of the tire market held by Group I elastomers is sheltered from
competition from TPEs. In 1991, the allocation of North American rubber use among the three rubber
categories was as follows: synthetic rubber, 68 percent; natural rubber, 24 percent, and TPEs, 8
29
percent. The International Institute of Synthetic Rubber Producers (IISRP) projects that SBR, BR,13
NBR, Neoprene, and natural rubber will each lose market share as thermoplastics use increases. EPDM
is the only Group I rubber whose market share is expected to grow. The end-use markets in which14
TPEs compete with natural and synthetic rubbers are shoe soles, polymer modifiers, adhesives, and
automotive parts.
Several Group I producers, however, also operate TPE capacity. Du Pont, for example, is the sole
supplier of Neoprene but also produces EPDM, several TPEs, and inputs to TPEs. Although thermoset
plastics are less expensive per kilogram than TPEs, the production process for TPEs is less complex and
has lower overall process costs. As Group I firms expand into the TPE market, one possibility is that
capacity for synthetic rubbers will be idled as TPE production becomes more profitable. In general,
TPEs are most likely to replace Group I elastomers in applications where the same performance
properties are either not necessary, or can be sacrificed in order to cut costs.
2.4.3 Exports of Group I Elastomers
Some measure of the extent of foreign competition can be obtained by comparing exports with
domestic production. The Foreign Trade Division of the United States Bureau of the Census collects
trade by polymer type according to a commodity coding system. In 1991, exports of all synthetic rubbers
accounted for 22 percent of domestic production. In 1991, exports of butyl rubber were 1.4 million
kilograms, or 20 percent of domestic production, while exports of NBR comprised 24 percent of
domestic production. Exports of polybutadiene rubber totalled 101 million kilograms in 1991 which
represented 27 percent of domestic production, and exports of EPDM comprised 29 percent of domestic
production. SBR exports were 152 million kilograms in 1991, or 23 percent of production, and SBL
exports were 22 percent of domestic production. (Neoprene, Hypalon, and EPI are not published as line
items by the Bureau of the Census.)15
2.5 MARKET DEMAND CHARACTERISTICS
The purpose of this section of the chapter is to characterize the demand side of the Group I
industries. The following sections present an examination of the factors that determine demand levels,
including the identification of the end-use markets, an evaluation of historical consumption patterns, and
an assessment of the role that imports play in satisfying domestic demand.
30
2.5.1 End-Use Markets for Group I Elastomers
In general, the primary use of Group I elastomers is as an input into the production of tires.
Globally, tires accounted for 60 percent of synthetic rubber use in 1991. The categorization of the
remaining 40 percent of synthetic rubber production into distinct end uses is complex. The Group I
elastomers are used as input for many diverse types of products, including components for machinery and
equipment (for example, belting and hoses), wire covering, construction (including roofing materials),
and consumer items. Synthetic rubbers are also used for waterproofing, sealing, and electrical and
thermal insulation.
In addition to the automotive market, other major end-use markets for synthetic rubbers include
construction products, industrial use, and miscellaneous applications, such as footwear, adhesives,
sealants, and electrical products. Market conditions affecting demand have developed in the non-tire
markets as well. Environmental concerns, and particularly new technology, have generated the need for
more resilient end-use products, causing one elastomer to gain market share at the expense of another. In
the manufacture of automobile and electrical parts in 1986, for example, SBR began to lose sales to
thermoplastic blends and EPDM, which possessed better heat resistance properties.
2.5.2 Demand Determinants
The bulk of synthetic rubber produced is sold by the producer to another manufacturer for use in a
manufacturing process (or construction) or for incorporation into some other product. Consequently,
demand levels are mainly determined by the overall conditions in the industries which use Group I
rubbers as inputs. The demand for Group I synthetic rubbers is primarily determined by price level, the
price of available substitutes, general economic conditions, and end-use market conditions. The degree
to which price level influences the quantity of elastomers demand is referred to as the price elasticity of
demand, which is explored later in this report. Due to the inherent substitutability among the synthetic
rubber types in Group I, price is often a significant demand determinant. Historical price trends from
1987 to 1991 are shown in constant dollars in Figure 2-4. Increased competition from TPEs in recent
years has contributed to downward pressure on prices. Polybutadiene and NBR prices have declined
since 1987, and price levels for the other Group I elastomers have experienced yearly fluctuations over
this time period.
31
In addition to price, the consumption of Group IV resins is determined by general economic
conditions and the health of end use markets. Overall, the depressed conditions of both the global and
domestic economies have had negative effects on synthetic rubber markets. The rate of growth in real
GDP from 1981 to 1992 was 28.4 percent overall, an average annual growth rate of 2.4 percent for this
12-year period, while the growth rate from year to year has ranged from a decrease of 1.2 percent to an
increase of 6.2 percent during this period. Since synthetic rubbers are tied directly to manufacturing
industries, slow GDP growth generally results in low growth levels for the synthetic rubber market.
The demand levels for synthetic rubber have historically followed a cyclical pattern which reflects
overall economic conditions and mirrors the fluctuations in demand for domestically produced tires,
automobiles, and other automotive products. Tires and tire products, for example, have historically
accounted for roughly half of the synthetic rubbers
32
FIGURE 2-4. PRICE LEVELS BY RUBBER TYPE
33
consumed in the United States, but changes in tire technology, such as smaller tires and improved tire
life, have in turn reduced the demand for butadiene-based elastomers. Two factors negatively
influencing demand are the growth in popularity of imported cars (which come equipped with foreign-
made tires) and the significant upturn in sales of imported replacement tires, whose low cost adversely
affects sales of retreaded tires.
Figure 2-5 presents the 10-year trends for the two major end uses of Group I rubbers: tires and
automotive components. Tire production has been relatively stable after increasing during the early
1980s. In contrast, automobile production has experienced more volatile production levels, and has been
declining since 1988. The recent declines in both end-use industries can be attributed to the trend of
consumers using their automobiles over a longer time period, and purchasing replacement tires for
existing vehicles.
2.5.3 Past and Present Consumption
Overall, sales levels for Group I elastomers have been in a slow growth period since 1987, with the
exception of SBR, which has shown more significant growth. Figure 2-6 presents historical sales trends
for the years 1987 through 1991 for the four main rubber types, as well as a category encompassing all
other elastomers. Each of the rubber types has maintained relatively stable sales levels over this period,
with the exception of SBR, whose sales have increased 33 percent.
2.5.4 Imports of Group I Elastomers
Imports as a percentage of domestic consumption range from 2 to 31 percent for Group I elastomers.
Trade data for EPI, Hypalon, and Neoprene were not available from the U.S. Bureau of the Census. In
1991, imports of butyl rubber were only 1.3 million kilograms, 2 percent of domestic consumption. As a
percentage of domestic consumption, NBR imports were 17.4 million kilograms, or 23 percent of
domestic NBR sales in 1991. In 1991, imports of polybutadiene were 71 million kilograms and accounted
for 31 percent of domestic polybutadiene sales. EPDM imports were 13 million kilograms in 1991,
which accounted for 7 percent of consumption. SBL imports were 25.5 million kilograms
34
FIGURE 2-5. TIRE AND AUTOMOBILE PRODUCTION
35
FIGURE 2-6. SALES OF SYNTHETIC RUBBER BY TYPE
36
in 1991, or 11 percent of domestic SBL consumption. Imports of SBR were 55.6 million kilograms,
which represented 9 percent of domestic consumption in 1991.20
2.6 MARKET OUTLOOK
This section presents quantitative capacity growth forecasts available from the literature for each
affected Group I industry. Forecasts are important to the EIA since future market conditions contribute
to the potential impacts of the NESHAP which are assessed for the fifth year after regulation.
As discussed in Section 2.4, the domestic supply of these synthetic rubbers will be influenced by
technology, production costs, and price. One of the underlying conditions that will ultimately affect the
supply outlook for synthetic rubber, given increased regulations, is the industry's projected production
capacity. Given that current capacity utilization is only at 69 percent of total capacity because of low
production and high prices, little expansion is planned in the next five years.21
Due to low levels of automobile production, synthetic rubber output has been falling for the past
three years. Overall, synthetic rubber producers are faced with weak demand in end-use markets,
increasing feedstock costs, and environmental regulation. Performance requirements from the
automotive industry are also changing in response to new fuel efficiency and emission standards.
The IISRP has projected positive, but low, levels of demand growth for each of the Group I
elastomers through 1997. These demand projections are shown in Table 2-9. With the exception of22
EPDM, which has an annual growth projection of 4 percent, demand for each of the Group I rubbers is
projected to grow between 0.5 percent and 2 percent per year. In contrast, the demand for TPEs is
projected to grow 7 percent annually between 1992 and 1997.
These low demand forecasts for Group I rubbers are based on slow growth in the tire and automotive
markets. Demand growth for polybutadiene, whose end uses are heavily reliant on the health of the
automotive market, is at a low 2 percent. Its use as an impact modifier and a polymer additive will result
in a modest increase in sales. The future growth predicted for EPDM demand is based on its increased23
use in roofing membranes. Although the current lag in housing construction in the United States has
negatively affected EPDM demand, its use outside of North America is expected to increase.
38
REFERENCES
1. U.S. Environmental Protection Agency. Office of Air Quality Planning and Standards. Polymersand Resins I Process Reference. Research Triangle Park, NC. EPA 90-26. May 1992.
2. Radian Corporation. Draft of Industry Profile on Synthetic Rubber Industry. Received from L.Sorrels. U.S. Environmental Protection Agency. May 1993.
3. SRI International, Inc. 1992 Directory of Chemical Producers. Menlo Park, CA. 1992.
4. U.S. Small Business Administration. "Small Business Size Standards; Final and Interim FinalRules." 13 CFR 121. Federal Register. December 21, 1989.
5. Dun & Bradstreet. Supplier Evaluation Reports for Group I Affected Firms. August 1993.
6. Standard & Poor's. Register of Corporations, Directors, and Executives. Volume 1. McGraw-Hill,Inc. New York. 1993.
7. Schiller. Why Tiremakers Are Still Spinning Their Wheels. Business Week. February 26, 1990.
8. Reference 5.
9. U.S. Department of Commerce, International Trade Commission. Synthetic Organic Chemicals: United States Production and Sales, 1970 through 1991. Time Series Data Request. June 1993.
10. Standard & Poor's, Inc. Industry Surveys: Chemicals. Vol. 160, No. 45. Sec. 1. November 5,1992.
11. Chemical Marketing Reporter. Elastomers '92. November 2, 1992.
12. Reference 10.
13. Chemical & Engineering News. Product Report: Thermoplastic Elastomers. May 4, 1992.
14. International Institute of Synthetic Rubber Producers. Worldwide Rubber Statistics. Houston, TX.1991
15. U.S. Department of Commerce, Bureau of the Census, Trade Data Inquiries and Control Section. Information Request. June 1993.
Applicable to butyl rubber, EPI, halobutyl, and Neoprene.2
64
A degree of uncertainty is associated with this method of demand estimation. The estimation is not
robust since the model results vary depending upon the instruments used in the estimation process, and as
a result of the correction methods for serial correlation. For these reasons, a sensitivity analysis of the
price elasticity of demand estimates is presented using a range of elasticities that differ by a plus one and
minus one standard deviation from those utilized in the analysis. A lower and upper bound estimate for
EPDM of -0.56 and -1.9, for NBR/NBL of -1.87 and -3.69, for SBL of -0.81 and -1.17, for SBR of -2.72
and -4.44, for BR of -1.71 and -2.37, and for Other Elastomers of -0.62 and -1.72 is assumed in this
sensitivity analysis. The results of the sensitivity analysis are reported in Appendix A.
3.3.3 Price Elasticity of Supply
The price elasticity of supply, or own-price elasticity of supply, is a measure of the responsiveness
of producers to changes in the price of a product. The price elasticity of supply indicates the percentage
change in the quantity supplied of a product resulting from each 1 percent change in the price of the
product.
3.3.3.1 Model Approach. Published sources of the price elasticity of supply using current data were
not readily available. For this reason, an econometric analysis of the price elasticity of supply for the
Polymers and Resins Group I industries was conducted. The approach used to estimate the price
elasticity of supply makes use of the production function. The theoretical methodology of deriving a
supply elasticity from an estimated production function will be briefly discussed, with the industry
production function defined as follows:
where:
Q = the quantity of each Group I elastomer produced by domestic facilities,S
L = the labor input, or number of labor hours,
K = real capital stock,
M = the material inputs, and
t = a time variable to reflect technology changes.
In a competitive market, market forces constrain firms to produce at the cost minimizing output
level. Cost minimization allows for the duality mapping of a firm's technology (summarized by the firm's
65
production function) to the firm's economic behavior (summarized by the firm's cost function). The total
cost function for a Group I facility is defined as follows:
where:
TC = the total cost of production, and
C = the cost of production (including cost of materials and labor).
All other variables have been previously defined.
This methodology assumes that capital stock is fixed, or a sunk cost of production. This assumption
is consistent with the objective of modeling the adjustment of supply to price changes after
implementation of controls. Firms will make economic decisions that consider those costs of production
that are discretionary or avoidable. These avoidable costs include production costs, such as labor and
materials, and emission control costs. In contrast, costs associated with existing capital are not avoidable
or discretionary. Differentiating the total cost function with respect to Q derives the following marginalS
cost function:
where MC is the marginal cost of production and all other variables have been previously defined.
Profit maximizing competitive firms will choose to produce the quantity of output that equates
market price, P, to the marginal cost of production. Setting the price equal to the preceding marginal cost
function and solving for Q yields the following implied supply function:S
where:
P = the price of the Group I elastomer,
LP = the price of labor, and
MP = the price of materials.
All other variables have been previously defined.
66
An explicit functional form of the production function may be assumed to facilitate estimation of the
model. For this analysis, the Cobb-Douglas, or multiplicative form, of the production function is
postulated. The Cobb-Douglas production function has the convenient property of yielding constant
elasticity measures. The functional form of the production function becomes:
where:
tQ = the sum of the industry output of Group I synthetic rubbers produced in
year t,
tK = the real capital stock in year t,
tL = the quantity of labor hours used to produce Group I synthetic rubbers in
year t,
tM = the material inputs in year t, and
K L MA, α , α , α , λ = parameters to be estimated by the model.
This equation can be written in linear form by taking the natural logarithms of both sides of the
equation. Linear regression techniques may then be applied. Using the approach described, the implied
supply function may be derived as:
where:
LP = the factor price of the labor input,
MP = the factor price of the material input, and
K = fixed real capital.
i iThe β and γ coefficients are functions of the α , the coefficients of the production function. The supply
elasticity, γ, is equal to the following:
67
It is necessary to place some restrictions on the estimated coefficients of the production function in
order to have well-defined supply function coefficients. The sum of the coefficients for labor and
L Mmaterials should be less than one. Coefficient values for α and α that equal to one result in a price
elasticity of supply that is undefined, and values greater than one result in negative supply elasticity
measures. For these reasons, the production function is estimated with the restriction that the sum of the
coefficients for the inputs equal one. This is analogous to assuming that the synthetic rubber industry
exhibits constant returns to scale, or is a long-run constant cost industry. This assumption seems
reasonable on an a priori basis, and is not inconsistent with the available data.
3.3.3.3 Estimated Model. The estimated model reflects the industry production function for the
Group I synthetic rubber industries, using annual time series data for the years from 1959 through 1991.
The following model was estimated econometrically:
where each of the variables and coefficients have been previously defined.
3.3.3.4 Data. The data used to estimate the model are enumerated in Table 3-5. This table contains
a list of the variables included in the model, the units of measure, and a brief description of the data. The
data for the price elasticity of supply estimation model includes: the value of domestic shipments in
millions of dollars; the price index for value of domestic shipments (value of domestic shipments
tdeflated by the price index represent the quantity variable, Q or the dependent variable in the analysis); a
68
TABLE 3-5. DATA INPUTS FOR THE ESTIMATION OF THE PRODUCTION FUNCTION FORGROUP I INDUSTRIES
Variable Unit of Measure Description
tQ
t
tK
tL
tM
Millions of dollars
Years
Millions of 1987 dollars
Thousand of labor man hours
Millions of dollars
The value of shipments for SIC code 2822deflated by the price index for value ofshipments1
Technology time trend
Real capital stock for SIC code 2822adjusted for capacity utilization1,2
Production worker hoursfor SIC code 28221
Dollar value of material input for SICcode 2822 deflated to real values using thematerials price index1
NOTES: Annual Survey of Manufactures.1
Federal Reserve Board.2
69
ttechnology time variable, t; real net capital stock adjusted for capacity utilization, K in millions of
t tdollars; the number of production labor manhours, L ; the material inputs in millions of dollars, M ; and
the price index for value of materials. Data to estimate the production function on a rubber-specific basis
were unavailable; therefore, data for SIC code 2822 is utilized for each of the variables previously
enumerated, with the exception of the time variable and the capacity utilization factor, which is on a 2-
digit SIC code level. The capital stock variable represents real net capital stock for SIC code 2822
adjusted for capacity utilization using the capacity utilization factor.
The capital stock variable represents the most difficult variable to quantify for use in the
econometric model. Ideally, this variable should represent the economic value of the capital stock
actually used by each facility to produce synthetic rubbers for each year of the study. The most
reasonable data for this variable would be the number of machine hours actually used to produce the
synthetic rubbers each year. These data are unavailable. In lieu of machine hours data, the dollar value
of net capital stock in constant 1987 prices, or real net capital stock, is used as a proxy for this variable.
However, these data are flawed in two ways. First, the data represent accounting valuations of capital
stock rather than economic valuations. This aberration is not easily remedied, but is generally considered
unavoidable in most studies of this kind. The second flaw involves capital investment that is idle and is
not actually used in production in a particular year. This error may be corrected by adjusting the capital
investment to exclude the portion of capital investment that is idle, and does not contribute directly to
production in a given year. In an effort to further refine the data, real capital stock was adjusted for
capacity utilization. This refinement results in a data input that considers the percentage of real capital
stock actually utilized annually in synthetic rubber production.
3.3.3.5 Statistical Results. A restricted least squares estimator was used to estimate the coefficients
iof the production function model. A log-linear specification was estimated with the sum of the α
restricted to unity. This procedure is consistent with the assumption of constant returns to scale. The
model was further adjusted to correct for first-order serial correlation using the Prais-Winsten algorithm.
The results of the estimated model are presented in Table 3-6. All of the coefficients have the expected
sign,
70
TABLE 3-6. ESTIMATED SUPPLY MODEL COEFFICIENTS FOR GROUP IINDUSTRIES
Variable Estimated Coefficients1
t time
tK Capital Stock
tL Labor
tM Materials
-0.022(0.033)
.401
(0.087)
0.149(0.101)
0.450(0.065)
NOTES: Standard errors are shown in parentheses.1
71
but only the capital stock and materials coefficient are significantly different from zero with a high
degree of confidence.
Using the estimated coefficients in Table 3-6 and the formula for supply elasticity shown in Section
3.3.3.1, Model Approach, the price elasticity of supply for the Group I industries is derived to be 1.49.
The calculation of statistical significance for this elasticity measure is not a straightforward calculation
since the estimated function is non-linear. No attempt has been made to assess the statistical significance
of the estimated elasticity. The corrections for serial correlation and the restricted model results yield the
standard measures of goodness of fit (R ) inaccurate. However, the ordinary least squares estimated2
model that is unrestricted and unadjusted for serial correlation has an R of 0.96.2
3.3.3.6 Limitations of the Supply Elasticity Estimates. The estimated price elasticity of supply for
the affected Group I industries reflects that the synthetic rubber manufacturing industry in the United
States will increase production of these products by 1.49 percent for every 1 percent increase in the price
of these products. The preceding methodology does not directly estimate the supply elasticities for the
individual elastomers due to a lack of necessary data. The assumption implicit in the use of this supply
elasticity estimate is that the elasticities of the individual products will not differ significantly from the
price elasticity of supply for all products categorized under SIC code 2822. This assumption does not
seem unreasonable since similar factor inputs are used to produce each of these synthetic rubbers.
The uncertainty of the supply elasticity estimate is acknowledged. To take this uncertainty into
account, a sensitivity analysis of the price elasticity supply was conducted. The results of a sensitivity
analysis of the price elasticity of supply are presented in Appendix A for a high-end and low-end
estimate of the price elasticity of supply of 2.49 and 0.49, respectively.
3.4 CAPITAL AVAILABILITY ANALYSIS
The capital availability analysis outlined in this section is designed to evaluate the impact of the
emission controls on the affected firms' financial performance and their ability to finance the additional
capital investment in emission control equipment. Sufficient financial data were available to conduct this
analysis on a firm level.
72
One measure of financial performance frequently used to assess the profitability of a firm is net
income before interest expense expressed as a percentage of firm assets, or rate of return on investment.
The pre-control rate of return on investment (roi) is calculated as follows:
i iwhere n is income before interest payments and a is total assets. A five year average is used to avoid
annual fluctuations that may occur in income data. The regulations could potentially have an effect on
i iincome before taxes, n , for firms in the industry and on the level of assets for firms in the industry, a .
The baseline average rate of return on investment for firms in the sample range from minus 6 percent for
Bridgestone/Firestone to 18 percent for BASF. The post-control return on investment (proi) is calculated
for each firm as follows:
where:
proi = post-control return on investment,
ª n = change in income before interest and after taxes resulting from implementation of
emission controls for each firm in the sample, and
ª k = change in investment or assets for each firm in the sample.
iThe change in a firm's net income, ª n , is calculated using the results of the partial equilibrium
model. A firm's post-control net income has the following two components: (1) the change in revenue
attributable to the change in price, and (2) the change in cost attributable to the firm's incurrence of
compliance costs. The net effect of these two components determines the impact of the proposed
NESHAP on firms' net income levels. The change in net income, or ª n, for each firm is calculated as
follows:
73
where:
1 oª P = the change in market price, or P - P ,
nq = the level of output for firm n, and
nª c = total annualized per unit cost of compliance (including taxes) for firm n.
An adjustment needs to be made for the marginal firm which will experience post-control changes in
production. For each marginal Group I firm, the change in net income is calculated as follows:
where:
1 o 1 0q = firm's post control production, or q - (Q - Q ),Sd Sd
oP = baseline market price, and
1 0ª q = decrease in domestic production, or Q - Q .Sd Sd
The change in net income is adjusted to appropriately consider tax effects of changes in income. For
affected firms which operate more than one affected facility, the effects of compliance costs on net
income and assets were aggregated to a firm level.
The ability of affected firms to finance the capital equipment associated with emission control is
also relevant to the analysis. Numerous financial ratios can be examined to analyze the ability of a firm
to finance capital expenditures. One alternative is a measure of historical profitability, such as rate of
return on investment. The approach used to analyze this measure has been previously described. The
bond rating of a firm is another indication of the credit worthiness of a firm, or the ability of a firm to
finance capital expenditures with debt capital. Such data are unavailable for many of the firms subject to
the regulation, and consequently, these measures are not analyzed. Ability to pay interest payments and
coverage ratios are two other criteria sometimes used to assess the capability of a firm to finance capital
expenditures. The data available to conduct the capital availability analysis based on these two criteria
were also unavailable.
74
Finally, the degree of debt leverage or debt-equity ratio of a firm is considered in assessing the
ability of a firm to finance capital expenditures. The pre-control debt-equity ratio is the following:
where:
d/e = the debt equity ratio,
d = debt capital, and
e = equity capital.
Since capital information is less volatile than earnings information, it is appropriate to use the latest
available information for this calculation. The baseline debt equity ratios for Group I firms range from
20 percent for Exxon Corporation to 68 percent for Bridgestone/Firestone. If one assumes that the
capital costs of control equipment are financed solely by debt, the debt-equity ratio becomes:
where:
pd/e = the post-control debt-equity ratio assuming that the control equipment costs are financed
solely with debt.
Obviously, firms may choose to issue capital stock to finance the capital expenditure or to finance
the investment through internally generated funds. Assuming that the capital costs are financed solely by
debt may be viewed as a worse case scenario.
The methods used to perform this capital availability analysis do have some limitations. The
approach matches 1991 debt and equity values with estimated capital expenditures for control equipment.
Average 1987 through 1991 income and asset measures are matched with changes in income and capital
expenditures associated with the control measures. The control cost changes and income changes reflect
1989 price levels. The financial data used in the analysis represent the most recent data available. It is
inappropriate to simply index the income, asset, debt, and equity values to 1992 price levels for the
following reasons. Assets, debt, and equity represent embedded values that are not subject to price level
75
changes except for new additions such as capital expenditures. Income is volatile and varies from period
to period. For this reason, average income measures are used in the study.
The methodology used in this analysis reflects a conservative approach to analyzing the changes
likely in financial ratios for the affected Group I firms. The potential for decreases in the cost of
production to occur for some firms after implementation of emission controls has not been considered.
Production costs which may decrease under post-control conditions include labor input and energy input
cost decreases. Annualized compliance costs are overstated from a financial income perspective, since
these costs include a component for earnings, or return on investment. In general, the approach followed
tends to overstate the negative impact of the proposed emission controls on the financial operations of the
affected Group I industries.
76
REFERENCES
1. Hyman, David N. Economics. Irwin Publishing. Homewood, IL. 1989. pp. 213-214.
2. U.S. Department of Commerce, International Trade Commission. Synthetic Organic Chemicals: U.S. Production and Sales. Time Series Data Request. Washington, DC. March 17, 1993.
3. U.S. Department of Commerce, Bureau of the Census, Trade Data Inquiries and Control Section. Data Request. Washington, DC. March 11, 1993.
4. U.S. Office of Management and Budget. Guidelines and Discount Rates for Benefit-Cost Analysisof Federal Programs. Circular Number A-94. Washington, D.C. October 29, 1992.
5. U. S. Department of Commerce, Bureau of the Census. Annual Survey of Manufactures. Washington, DC. 1959-1991.
6. U.S. Environmental Protection Agency. Industry Profile for the Polymers and Resins Group INESHAP - Revised Draft. Research Triangle Park, NC. September 14, 1993.
7. Pindyck, Robert S. and Daniel L. Rubinfeld. Econometric Models and Economic Forecasts, 2ndEdition. McGraw Hill Publishing. 1981. pp. 174-201.
8. Reference 2.
9. Reference 5.
10. U.S. Department of Commerce, Bureau of Economic Analysis. Business Statistics 1963-1991. 27thEdition. Washington, DC. June 1992.
11. Board of Governors of the Federal Reserve System, Division of Research and Statistics. IndustrialProduction and Capacity Utilization Data Request. Washington, DC. August 18, 1994.
77
78
4.0 CONTROL COSTS, ENVIRONMENTAL IMPACTS,
COST-EFFECTIVENESS
4.1 INTRODUCTION
Inputs to the model outlined in the previous chapter include the quantitative data summarized in
Chapter 2.0 and control cost estimates provided by EPA. This chapter summarizes the cost inputs used
in this EIA which were provided on a facility level for each of the affected Group I industries.
A formal Benefit Cost Analysis (BCA) requires estimates of economic costs associated with
regulation, which do not correspond to emission control costs. This chapter presents the progression of
steps which were taken to arrive at estimates of economic costs based on the emission control cost
estimates. The environmental impacts associated with the chosen regulatory option in this analysis are
summarized and the cost-effectiveness of the regulatory option is presented.
4.2 CONTROL COST ESTIMATES
Control cost estimates and emission reductions were provided by EPA's engineering contractor on a
facility level. The cost estimates provided by EPA represent the impact of bringing each facility from
existing control levels to the control level defined by each regulatory alternative. The emission points for
which costs were provided include: storage tanks, equipment leaks, wastewater streams, and front- and
back-end process vents. The control costs estimated for each elastomer facility can be divided into fixed
and variable components. Fixed costs are constant over all levels of output of a process, and usually
entail plant and equipment. Variable costs will vary as the rate of output changes. Annual and variable
cost estimates include costs for monitoring, recordkeeping, and reporting (MRR) requirements. The
costs were calculated for existing emission sources only given that little new source construction is likely
in these industries within the next five years.
79
Table 4-1 presents the national annualized cost estimates for controlling existing sources for each of
the regulated industries in the fifth year after promulgation of the NESHAP. Emission control costs are1
the annualized capital and annual operating and maintenance costs of controls based on the assumption
that all affected synthetic rubber facilities install controls. The engineering contractor established a
baseline level of control for each facility, determined which facilities would be required to install
controls to meet the provisions of the regulatory alternative, and estimated the cost of the anticipated
controls. The single facility in the Hypalon subcategory would not require any additional control to meet
the level of control. For this reason, Hypalon is not included in the EIA results presented later in this
report. The controls associated with each of the emission points in the remaining Group I industries are
discussed separately below.
The methodologies used to estimate the costs for the expected regulatory alternative are the same as
the methodologies used to estimate the costs of the HON rule. For storage tanks, required control2
measures range from floating roofs to closed vent systems routed to a control device. For equipment
leaks, facilities have several compliance options. Facilities are required to develop and implement leak
detection and repair programs or to install certain types of emission-reducing, or emission-eliminating,
equipment. The affected facilities that produce styrene-butadiene rubber by emulsion and Hypalon are in
compliance with HON equipment leak provisions. Therefore, no emission reductions are achieved, or
equipment leak control costs incurred, at facilities producing these two types of elastomers. Emission
reductions and compliance costs for which additional control is necessary were calculated as the
incremental emission reductions and costs between the existing control program and the HON level.
Costs for equipment leak provisions were based on the calculation used in the HON. For process vents,
the proposed provisions also resemble the HON. Control may be in the form of a 98 percent reduction in
emissions using add-on control, or a process change that alters the vent stream characteristics. For three
subcategories (styrene-butadiene rubber by emulsion,
80
TABLE 4-1. SUMMARY OF GROUP I NESHAP COSTS IN THE FIFTH YEAR BY ELASTOMER INDUSTRY1
Group I Industry
Fifth Year
Capital Costs
(1989 Dollars)
Annual Fifth
Year Costs
(1989 Dollars)
Annual HAP
Emission Reduction
(Mg/yr)
Cost-Effectiveness
($/Mg)
Butyl Rubber $691,158 $1,458,870 596 $2,448
EPDM $5,956,585 $4,589,591 2,087 $2,199
EPI $491,203 $296,582 124 $2,392
Halobutyl Rubber $328,055 $572,946 335 $1,710
Hypalon $0 $0 0 $0
NBL $464,737 $291,467 140 $2,082
NBR $397,265 $675,971 365 $1,852
Neoprene $560,205 $959,728 354 $2,711
SBL $1,480,479 $1,212,387 583 $2,080
SBR $3,941,869 $2,190,864 238 $9,205
BR $11,780,263 $8,745,806 1,519 $5,758
TOTAL FOR REGULATORY ALTERNATIVE $26,091,819 $20,994,211 6,341 $3,311
styrene-butadiene and polybutadiene rubber by solution, and ethylene-propylene rubber), the regulatory
alternative for back-end process vents is an emission limit based on production levels. The regulatory
alternative for back-end process vents at all other subcategories is not expected to require additional
control beyond the baseline. For wastewater, the NESHAP provisions require that wastewater be kept in3
tanks, impoundments, containers, drain systems, and other vessels that do not allow exposure to the
atmosphere until it is recycled or treated to reduce HAP concentration. Costs for wastewater provisions
were also developed using HON methodologies.
As shown in Table 4-1, the total nationwide annualized cost for implementation of the regulatory
alternative is $21 million for the 10 affected synthetic rubber industries, excluding Hypalon (and
including MRR costs). The majority of these costs are estimated for controlling HAP emissions
occurring as the result of the production of EPDM, or the production of BR/SBR by a solution process.
Table 4-1 also presents the HAP emission reductions associated with control at the four emission points
and the calculated cost-effectiveness for each industry. The cost effectiveness of this regulation ranges
from $1,710 per megagram to $9,205 per megagram, or an average of $3,311 per megagram of HAP
reduced. Table 4-1 also shows the total investment capital costs by Group I industry. Total capital
investment costs are estimated to be $26 million for existing sources five years subsequent to
promulgation of the NESHAP.
4.3 ESTIMATES OF ECONOMIC COSTS
Air quality regulations affect society's economic well-being by causing a reallocation of productive
resources within the economy. Resources are allocated away from the production of goods and services
(Group I elastomers) to the production of cleaner air. Estimates of the economic costs of cleaner air
require an assessment of costs to be incurred by society as a result of emission control measures. By
definition, the economic costs of pollution control are the opportunity costs incurred by society for
productive resources reallocated in the economy to pollution abatement. The economic costs of the
regulation can be measured as the value that society places on goods and services not produced as a
result of resources being diverted to the production of improved air quality. The conceptually correct
valuation of these costs requires the identification of society's willingness to be compensated for the
foregone consumption opportunities resulting from the regulation. In contrast to the economic cost of
regulation, emission compliance costs consider only the direct cost of emission controls to the industry
affected by the regulation. Economic costs are a more accurate measure of the costs of the regulation to
82
society than an engineering estimate of compliance costs. However, compliance cost estimates provide
an essential element in the economic analysis.
Economic costs are incurred by consumers, producers, and society at large as a result of pollution
control regulations. These costs are measured as changes in consumer surplus, producer surplus, and
residual surplus to society. Consumer surplus is a measure of well-being, or of the welfare of consumers
of a good, and is defined as the difference between the total benefits of consuming a good and the market
price paid for the good. Pollution control measures will result in a loss in consumer surplus due to higher
prices paid for Group I elastomers and to the deadweight loss in surplus caused by reduced output of
these elastomers in the post-control market.
Producer surplus is a measure of producers' welfare that reflects the difference between the market
price charged for a product and the marginal cost of production. Pollution controls will result in a
change in producer surplus that consists of three components. These components include: surplus gains
relating to increased revenues experienced by firms in the Group I industries attributable to higher post-
control prices, surplus losses associated with increased costs of production for annualized emission
control costs, and surplus losses due to reductions in post-control output. The net change in producer
surplus is the sum of these surplus gains and losses.
Additional adjustments, or changes in the residual surplus to society, are necessary to reflect the
economic costs to society of pollution controls, and these adjustments are referred to as the change in
residual surplus to society. Specifically, adjustments are necessary to consider tax gains or losses
associated with the regulation and to adjust for differences between the social discount rate and the
private discount rate. Since control measures involve the purchase of long-lived assets, it is necessary to
annualize the cost of emission controls. Annualization of costs require the use of a discount rate, or the
cost of capital. The private cost of capital (assumed to be 10 percent) is the relevant discount rate to use
in estimating annualized compliance costs and market changes resulting from the regulation. Firms in
the Group I industries will make supply decisions in the post-control market based upon increases in the
costs of production. The private cost of capital more accurately reflects the capital cost to firms
associated with the pollution controls. Alternatively, the social costs of capital (assumed to be 7 percent)
is the relevant discount rate to consider in estimating the economic costs of the regulation. The economic
cost of the regulation represents the cost of the regulation to society, or the opportunity costs of resources
displaced by emission controls. A risk-free discount rate, or the social discount rate, better reflects the
capital cost of the regulation to society.
83
The sum of the change in consumer surplus, producer surplus, and residual surplus to society
constitutes the economic costs of the regulation. Table 4-2 summarizes the economic costs associated
with the regulatory alternative. The total economic cost for all of the affected industries combined is $15
million (1989 $).
4.4 ESTIMATED ENVIRONMENTAL IMPACTS
The primary purpose of the NESHAP is to reduce HAP emissions from Group I facilities. Table 4-3
reports estimates of annual emission reductions associated with the chosen alternative. The HAP
emission reductions were calculated based on the application of sufficient controls to each emission point
to bring each point into compliance with the regulatory alternative. The estimate of total HAP emission
reductions is 6,341 Mg per year. This represents a nearly 50 percent reduction from the industry
baseline.
4.5 COST EFFECTIVENESS
Economic cost effectiveness is computed by dividing the annualized economic costs by the
estimated emission reductions. The NESHAP has a calculated total cost effectiveness of $2,384 per
megagram of HAP reduced.
Generally, a dominant alternative results in the same or higher emission reduction at a lower cost
than all other alternatives. Because this analysis evaluated only one alternative, however, there is no
basis for comparison.
84
TABLE 4-2. ANNUAL ECONOMIC COST ESTIMATES FOR THE POLYMERS AND RESINSGROUP I REGULATION(millions of 1989 dollars)
Group I Industry
Change inConsumerSurplus*
Change inProducerSurplus*
Change inResidualSurplus*
Total Loss InSurplus*
Butyl Rubber ($0.48) ($0.59) ($0.29) ($1.36)
EPDM ($3.61) $0.27 $0.45 ($2.89)
EPI ($0.11) ($0.11) ($0.03) ($0.25)
Halobutyl Rubber ($0.19) ($0.24) ($0.11) ($0.54)
NBL ($0.12) ($0.12) ($0.04) ($0.28)
NBR ($0.41) ($0.17) ($0.07) ($0.65)
Neoprene ($0.64) ($0.01) $0.02 ($0.63)
SBL ($2.97) $1.30 $0.78 ($0.89)
SBR ($2.52) $0.57 $0.50 ($1.45)
BR ($9.12) $1.56 $1.38 ($6.18)
Total ($20.17) $2.46 $2.59 ($15.12)
NOTE: *Brackets indicate economic costs.
85
TABLE 4-3. ESTIMATED ANNUAL REDUCTIONS IN EMISSIONS AND COST-EFFECTIVENESSASSOCIATED WITH THE CHOSEN REGULATORY ALTERNATIVE
Group I IndustryHAP Emission Reduction
(Megagrams/Yr)HAP Cost Effectiveness*
($/Year)
Butyl Rubber 596 $2,282
EPDM 2,087 $1,385
EPI 124 $2,016
Halobutyl Rubber 335 $1,612
NBL 140 $2,000
NBR 365 $1,781
Neoprene 354 $1,780
SBL 583 $1,527
SBR 238 $6,092
BR 1,519 $4,068
Total 6,341 $2,384
NOTES: *Cost-effectiveness is computed as estimated annualized economic costs divided by estimated emissions reduced. Comparisons are made between the regulatory alternative and baseline conditions.
86
REFERENCES
1. Phil Norwood, EC/R Incorporated. Letter to Larry Sorrels, EPA/OAQPS/CEIS. Polymers andResins I: Facility-Specific Summary of Costs. Durham, NC. September 14, 1994.
2. U.S. Environmental Protection Agency. "Hazardous Air Pollutant Emissions from Process Units inthe Synthetic Organic Manufacturing Industry % Background Information for Proposed Standards. Volume 1B: Control Technologies." Draft EIS. EPA-453/D-92-016b. Research Triangle Park,NC. November 1992.
3. Phil Norwood, EC/R Incorporated. Letter to Leslie Evans, EPA/OAQPS/ESD/CPB. PreliminaryImpacts Analysis: Polymers and Resins I. Durham, NC. July 8, 1994.
4. King, Bennett. Pacific Environmental Services. Letter to Larry Sorrels. U.S. EnvironmentalProtection Agency. Revised Draft Costs Impacts for Court-Order Group I Resins. ResearchTriangle Park, NC. September 12, 1994.
87
88
5.0 PRIMARY ECONOMIC IMPACTS AND CAPITAL
AVAILABILITY ANALYSIS
5.1 INTRODUCTION
Estimates of the primary economic impacts resulting from implementation of the NESHAP and the
results of the capital availability analysis are presented in this chapter. Primary impacts include changes
in the market equilibrium price and output levels, changes in the value of shipments or revenues to
domestic producers, and plant closures. The capital availability analysis assesses the ability of affected
firms to raise capital and the impacts of control costs on firm profitability.
5.2 ESTIMATES OF PRIMARY IMPACTS
The partial equilibrium model is used to analyze the market outcome of the regulation. As outlined
in Chapter 3 of this report, the purchase of emission control equipment will result in an upward vertical
shift in the domestic supply curve for each affected Group I market. The height of the shift is determined
by the after-tax cash flow required to offset the per unit increase in production costs. Since the control
costs vary for each of the affected Group I facilities, the post-control supply curve is segmented, or a step
function. Underlying production costs for each facility are unknown; therefore, a worst case assumption
was necessary. The facilities with the highest control costs per unit of production were assumed to also
have the highest pre-control per unit cost of production. Thus, firms with the highest per unit cost of
emission control are assumed to be marginal in the post-control market.
Foreign demand and supply are assumed to have the same price elasticities as domestic demand and
supply, respectively. The United States had a positive trade balance for each of the Group I synthetic
rubbers in 1991. Net exports are therefore positive for each Group I industry in the baseline market
models. Foreign and domestic post-control supply are added together to form the total post-control
89
market supply. The intersection of this post-control supply with market demand will determine the new
market equilibrium price and quantity in each Group I industry.
Table 5-1 presents the primary impacts predicted by the partial equilibrium model. The range of
anticipated price increases vary from a low of $0.002 for halobutyl to a high of $0.022 for EPI per
kilogram produced. The percentage price increases for each Group I elastomer range from a high of 2.5
percent for butyl to a low of 0.31 percent for NBR. Production is expected to decrease by 47.76 million
kilograms for all Group I elastomers collectively, decreases in domestic production ranging from 0.69
percent for NBL to 4.95 percent for butyl rubber.
The value of domestic shipments, or revenues, for domestic producers is expected to decrease for
each affected Group I industry by a total of $29.6 million for all Group I industries combined. The
predicted decreases in annual revenues for individual products range from a low of $0.08 million for EPI
to a high of $15.24 for BR (1989 dollars). The percent changes range from a low of 0.35 percent for
EPDM to a high of 2.7 percent for BR. Economic theory predicts that revenue decreases are expected to
occur when prices are increased for products which have an elastic price elasticity of demand, holding all
other factors constant. A revenue decrease results because the percentage increase in price is less than
the percentage decrease in quantity for goods with elastic demand. The estimated revenue decreases in
each of the Group I industries follows this trend. It is anticipated that none of the affected facilities will
close or shut down as a result of the NESHAP.
The estimated primary impacts reported for the Group I elastomers depend on the set of parameters
used in the partial equilibrium model. Two of the parameters, the price elasticity of demand and the
price elasticity of supply, have some degree of estimation uncertainty. For this reason, a sensitivity
analysis was conducted. The results of these
90
TABLE 5-1. SUMMARY OF PRIMARY ECONOMIC IMPACTS OF POLYMERS AND RESINSGROUP I NESHAP
Hampshire Chemical, and Zeon Chemical. Of these 5 firms, American Synthetic Rubber Corporation
and Ameripol Synpol are affiliated with larger business entities; there are, therefore, 3 affected small
firms.
7.4 SMALL BUSINESS IMPACTS
Since the results of the partial equilibrium analysis lead to the conclusion that none of the affected
Group I facilities are at risk of closure, this criterion for adverse small business effects is not met.
The remaining criterion for determining the significance of small business impacts is to analyze the
total annual compliance costs as a percentage of sales for small firms. Sales and annualized compliance
cost data for the three small businesses are shown in Table 7-1. In 1991, sales for these firms ranged
from $94 million (1989 dollars) for DSM Copolymer to $195 million (1989 dollars) for Hampshire
Chemical. Total compliance cost estimates for these firms based on 1991 production range from $82,577
for Hampshire Chemical to $799,835 for DSM Copolymer. Expressed as percentages of total sales, costs
range from 0.04 percent for Hampshire Chemical to 0.85 percent for DSM Copolymer. Because the
104
ratios in Table 7-1 are low, the conclusion is drawn that a significant number of small businesses are not
adversely affected by the proposed regulations.
105
TABLE 7-1. COMPLIANCE COSTS AS A PERCENTAGE OF SALES AT SMALL GROUP I FIRMS
Firm1991 Sales
(Million 1989 $)1
Compliance Costs(Million 1989 $) Cost-to-Sales Ratio
DSM Copolymer $ 94 $0.80 0.85%
Hampshire Chemical $195 $0.08 0.04%
Zeon Chemical $98 $0.30 0.31%
NOTE: Economic Indicators1
106
REFERENCES
1. U.S. Congress, Council of Economic Advisors. Economic Indicators: September 1993. Preparedfor the Joint Economic Committee. Washington, DC. September 1993.
107
APPENDIX A
SENSITIVITY ANALYSIS
The sensitivity analysis contained in this Appendix explores the degree to which the results
presented earlier in this report are sensitive to the estimates of the price elasticities of demand and supply
which were used as inputs to the models. The analysis of the price elasticity of demand will presume the
supply elasticity is 1.49 as hypothesized in the partial equilibrium model. Alternatively, the sensitivity
analysis of supply elasticities will assume that the demand elasticity estimates postulated in the model
and listed under the Elasticity Measure column in Table A-1 are accurate for each of the Group I
elastomers.
The results presented in this appendix are based upon price elasticities of demand estimates for each
Group I industry that differ by one standard error from those used in the model. Table A-1 presents the
alternative measures of price elasticities of demand for each Group I elastomer.
TABLE A-1. PRICE ELASTICITY OF DEMAND ESTIMATES
Group I Industry Elasticity Measure High Estimate Low Estimate
Butyl -1.17 -1.72 -0.62
EPDM -1.23 -1.90 -0.56
EPI -1.17 -1.72 -0.62
Halobutyl 1.17 -1.72 -0.62
NBL -2.78 -1.87 -3.69
NBR -2.78 -1.87 -3.69
Neoprene -1.17 -1.72 -0.62
SBL -0.99 -1.17 -0.81
SBR -3.58 -4.44 -2.72
BR -2.04 -2.37 -1.71
The results of the sensitivity analysis results relative to demand elasticity estimates are presented in
Tables A-2 and A-3. Table A-2 reports results under the low-end estimate of the price elasticity of
demand scenario, and Table A-3 reports results under the high-end measure of the price elasticity of
demand scenario.
A-1
The results of the low-end demand elasticity scenario differ very little from the reported results
presented in Chapter 5 of this report. The signs of the changes in price and quantity are unchanged, and
the relative size of the changes are not significantly altered. Revenue changes become slightly positive
for some Group I industries with inelastic price elasticity of demand measures. The results of this
analysis tend to present relatively more favorable results for the Group I industries with lower output and
revenue declines and larger price increases. In general, the scenario for the high-end elasticity results in
primary market impacts that do not differ significantly from previously reported results for price
increases and quantity decreases for most of the Group I industries. However, the results are less
favorable for Group I industries with lower price increases and greater output and revenue decreases.
TABLE A-2. SENSITIVITY ANALYSIS FOR ESTIMATED PRIMARY IMPACTS: LOW-END PRICE ELASTICITY OF DEMAND SCENARIO1
Group I IndustryMarket
Price Change (%)
DomesticMarket
Output Change (%)
Change in the Value of Shipments (%)
Butyl 3.14 (4.01) (1.00)
EPDM 1.15 (0.79) 0.35
EPI 1.03 (0.96) (0.06)
Halobutyl 0.86 (1.11) (0.26)
NBL 0.23 (0.62) (0.39)
NBR 0.39 (1.05) (0.66)
Neoprene 1.40 (1.08) 0.31
SBL 0.69 (0.72) (0.04)
SBR 0.49 (1.46) (0.98)
BR 2.10 (4.23) (2.22)
NOTES: Brackets indicate decreases or negative values.1
A-2
TABLE A-3. SENSITIVITY ANALYSIS FOR ESTIMATED PRIMARY IMPACTS: HIGH-END PRICE ELASTICITY OF DEMAND SCENARIO1
Group I IndustryMarket Price Change
(%)
DomesticMarket Quantity
Change (%)
Change in the Value ofShipments (%)
Butyl 2.07 (5.57) (3.61)
EPDM 0.70 (1.46) (0.77)
EPI 0.68 (1.49) (0.82)
Halobutyl 0.56 (1.54) (0.98)
NBL 0.15 (0.74) (0.59)
NBR 0.26 (1.25) (1.00)
Neoprene 0.93 (1.79) (.88)
SBL 0.60 (0.86) (0.27)
SBR 0.35 (1.67) (1.33)
BR 1.74 (4.75) (3.09)
NOTES: Brackets indicate decreases or negative values.1
The results of the sensitivity analyses under the low-end and high-end price elasticity of supply
scenarios are reported in Table A-4 and Table A-5, respectively. The high estimate used in this analysis
was 2.49, and the low-end estimate used in this analysis was 0.49. Again, the results do not differ greatly
from those used in the partial-equilibrium model. The results under the low-end supply elasticity
scenario are slightly more favorable to the Group I industries than those previously reported in Chapter 5,
with smaller output and revenue decreases. The price increases decline, however. In contrast, the results
under the high-end elasticity scenario are generally less favorable for the affected industries.
In summary, the results of these sensitivity analyses do not indicate that the model results are overly
sensitive to reasonable changes in the price elasticities of demand or supply. This conclusion provides
support for greater confidence in the reported model results.
A-3
TABLE A-4. SENSITIVITY ANALYSIS FOR ESTIMATED PRIMARY IMPACTS: LOW-END PRICE ELASTICITY OF SUPPLY SCENARIO
Group I IndustryMarket Price Change
(%)
DomesticMarket Quantity
Change (%)
Change in the Value ofShipments (%)
Butyl 1.34 (2.24) (0.94)
EPDM 0.45 (0.60) (0.15)
EPI 0.43 (0.61) (0.18)
Halobutyl 0.36 (0.61) (0.25)
NBL 0.08 (0.28) (0.20)
NBR 0.13 (0.47) (0.34)
Neoprene 0.59 (0.76) (0.17)
SBL 0.35 (0.40) (0.05)
SBR 0.17 (0.64) (0.48)
BR 0.88 (2.02) (1.16)
NOTES: Brackets indicate decreases or negative values.1
A-4
TABLE A-5. SENSITIVITY ANALYSIS FOR ESTIMATED PRIMARY IMPACTS: HIGH-END PRICE ELASTICITY OF SUPPLY SCENARIO
Group I IndustryMarket Price Change
(%)
DomesticMarket Quantity
Change (%)
Change in the Value ofShipments (%)
Butyl 2.99 (6.90) (4.12)
EPDM 1.06 (1.53) (0.49)
EPI 0.99 (1.70) (0.72)
Halobutyl 0.82 (1.92) (1.11)
NBL 0.25 (0.99) (0.75)
NBR 0.42 (1.68) (1.27)
Neoprene 1.35 (1.93) (0.60)
SBL 0.76 (1.03) (0.28)
SBR 0.56 (2.24) (1.69)
BR 2.46 (6.08) (3.78)
NOTES: Brackets indicate decreases or negative values.1